Caffeine inhibition of prereplication repair of mitomycin C-induced DNA damage in human peripheral lymphocytes

Genotoxicity of dichlorvos in strains of Drosophila melanogaster defective in DNA repair

Dichlorvos (DDVP), an organophosphate pesticide, is reported to be genotoxic at high concentrations. However, the roles of DNA damage repair pathways in DDVP genotoxicity are not well characterized. To test whether pre- and post-replication pathways are involved, we measured changes in DNA migration (Comet assay) in the midgut cells of Drosophila melanogaster Oregon R+ larvae and in some mutants of pre- (mei-9, mus201, and mus207) and post- (mei-41 and mus209)replication DNA repair pathways. Insects were exposed to environmentally relevant concentrations of DDVP (up to 15ng/ml) for 48h. After insect exposure to 0.15ng/ml DDVP, we observed greater DNA damage in pre-replication repair mutants; effects on Oregon R+ and post-replication repair mutants were insignificant. In contrast, significant DNA damage was observed in the post-replication repair mutants after their exposure to 1.5 and 15ng/ml DDVP. The pre-replication repair mutant mus207 showed maximum sensitivity to DDVP, suggestive of alkylation damage to DNA. We also examined mutants (SOD- and urate-null) that are sensitive to oxidative stress and the results indicate that significant oxidative DNA damage occurs in DDVP-exposed mutants. This study suggests involvement of both pre- and post-replication repair pathways against DDVP-induced DNA damage in Drosophila, with oxidative DNA damage leading to genotoxicity.

In vivo synergistic cytogenetic effects of aminophylline on lymphocyte cultures from patients with lung cancer undergoing chemotherapy

BACKGROUND

The anti-cancer and cytogenetic effects of aminophylline (AM) have been demonstrated in several clinical trials. The aim of the present study was to investigate the in vivo cytogenetic effects of AM in newly diagnosed patients with small cell (SCLC) and non-small cell lung cancer (NSCLC), receiving chemotherapy for the first time.

METHODS

Sister chromatid exchanges (SCEs) and proliferation rate index (PRI) were evaluated in peripheral blood lymphocyte cultures from six patients with SCLC and six patients with NSCLC after the in vitro addition of AM and after the in vivo administration of AM in patients receiving chemotherapy.

RESULTS

The in vitro addition of AM significantly increased SCEs only in SCLC patients (p<0.001). The in vivo administration of AM after chemotherapy increased SCEs in both cancer types (SCLC: p<0.001, NSCLC: p=0.003) and this increase was synergistic, the rates of SCEs in the presence of AM were higher than the expected SCE values if the increases above background for chemotherapy and AM were independent and additive (SCLC: p<0.001, NSCLC: p=0.008). Although in both groups of patients cell division delays were observed after the combined chemotherapy plus in vivo AM treatment, the correlation between the magnitude of the SCE response and the PRI depression was not statistically significant (p>0.05).

CONCLUSIONS

These observations suggest that AM enhances the results of concurrently administered chemotherapy by synergistically increasing its cytogenetic effects in patients with lung cancer.

Tracing the tracks of genotoxicity by trivalent and hexavalent chromium in Drosophila melanogaster

Mutagen sensitive strains (mus) in Drosophila are known for their hypersensitivity to mutagens and environmental carcinogens. Accordingly, these mutants were grouped in pre- and post-replication repair pathways. However, studying mutants belonging to one particular repair pathway may not be adequate for examining chemical-induced genotoxicity when other repair pathways may neutralize its effect. To test whether both pre-and post-replication pathways are involved and effect of Cr(III)- and Cr(VI)-induced genotoxicity in absence or presence of others, we used double mutant approach in D. melanogaster. We observed DNA damage as evident by changes in Comet assay DNA migration in cells of larvae of Oregon R(+) and single mutants of pre- (mei-9, mus201 and mus210) and post- (mei-41, mus209 and mus309) replication repair pathways and also in double mutants of different combinations (pre-pre, pre-post and post-post replication repair) exposed to increasing concentrations of Cr(VI) (0.0, 5.0, 10.0 and 20.0 μg/ml) for 48 h. The damage was greater in pre-replication repair mutants after exposure to 5.0 μg/ml Cr(VI), while effects on Oregon R(+) and post replication repair mutants were insignificant. Post-replication repair mutants revealed significant DNA damage after exposure to 20.0 μg/ml Cr(VI). Further, double mutants generated in the above repair categories were examined for DNA damage following Cr(VI) exposure and a comparison of damage was studied between single and double mutants. Combinations of double mutants generated in the pre-pre replication repair pathways showed an indifferent interaction between the two mutants after Cr(VI) exposure while a synergistic interaction was evident in exposed post-post replication repair double mutants. Cr(III) (20.0 μg/ml) exposure to these strains did not induce any significant DNA damage in their cells. The study suggests that both pre- and post-replication pathways are affected in Drosophila by Cr(VI) leading to genotoxicity, which may have consequences for metal-induced carcinogenesis.

Coffee and the immune system

The effect of coffee consumption on the immune system, studied in 15 men and women, showed that the responses to PHA and Con A were about one-third lower during coffee drinking compared to a period of abstinence from coffee (117335, 99856 and 181236, 153315, P less than 0.004, 0.009 respectively). There was no effect on total T- or B-cells. There was no statistically significant change in the number of suppressor T-cells (20, 26; P = 0.1) or NK cells (20, 26; P = 0.014). Chemotaxis was higher in the coffee period at all concentrations. This exploratory study suggests that coffee intake modifies various measures of the immune function. The clinical relevance of the findings is not clear, and further studies aimed at delineating the constituents responsible for the effects observed are recommended.

Factors that influence formation of sister chromatid exchanges in human blood lymphocytes

Sister chromatid exchange (SCE) reflects an interchange of DNA sequences between helices in a replicating chromosome. This was initially accomplished by Taylor and colleagues (1957) using tritiated thymidine incorporation followed by autoradiography. The development of an elegant technique for differential staining of sister chromatids by incorporating a thymidine analog, 5-bromodeoxyuridine (BrdU) has greatly simplified the detection of SCEs in metaphase chromosomes. In recent years, the analysis of SCE has been considered to be a highly sensitive and additional (i.e., with chromosome aberrations) end point for measuring mutagenic/carcinogenic potential of various environmental agents and is increasingly being used to detect and differentiate among chromosome fragility human diseases that predispose to neoplasia. Attention has been focused to see if the induction of SCEs in lymphocyte cultures can be used as a reliable "biological dosimeter" for genetic risk assessment and to monitor the exposed populations. Several physical or preparatory as well as biological factors that modify the response and formation of SCEs make the monitoring difficult. The purpose of this article is to review and analyze these factors to facilitate an effective development of a standard protocol for SCE testing and for appropriate evaluation of test results. This may also provide clues to understand the yet unknown molecular mechanism(s) and biological significance of SCE formation.

Effects of repair inhibition in the G1 phase of clastogen-treated human lymphocytes on the frequencies of chromosome-type and chromatid-type aberrations and sister-chromatid exchanges

It has been shown that certain types of DNA lesions induced by an S-dependent clastogen are converted to chromosome-type aberrations when their repair is inhibited in the G1 phase of the cell cycle. The purpose of the present study was to investigate which kinds of repair inhibitors have the ability to induce chromosome-type aberrations in cells having DNA lesions and which kinds of DNA lesions will be converted to chromosome-type aberrations when their repair is inhibited. For this purpose, human peripheral blood lymphocytes, which were treated with a clastogen in their G0 phase, were post-treated with one of several kinds of repair inhibitors in the G1 phase, and resulting frequencies of both chromosome-type and chromatid-type aberrations as well as of sister-chromatid exchanges (SCEs) were compared with those of the control cultures: chromatid-type aberrations and SCEs were adopted as cytogenetic indicators of lesions remaining in S and G2 phases. Chemicals used for the induction of DNA lesions were 4-nitroquinoline 1-oxide (4NQO), methyl methanesulfonate (MMS) and mitomycin C (MMC); inhibitors used were excess thymidine (dThd), caffeine, hydroxyurea (HU), 5-fluoro-2'-deoxyuridine (FdUrd), 1-beta-D-arabinofuranosylcytosine (ara C), 9-beta-D-arabinofuranosyladenine (ara A), 1-beta-D-arabinofuranosylthymine (ara T) and aphidicolin (APC). Induction of chromosome-type aberrations was observed in cells pretreated with 4NQO or MMS followed by ara C, ara A, ara T or APC, whereas other combinations of a clastogen and an inhibitor did not induce them. Among the inhibitors, ara C alone induced chromosome-type aberrations in cells without pretreatment. Chromatid-type aberrations were increased only in cells pretreated with MMC and their frequency was enhanced further by post-treatment with ara C. All of the clastogens used in the present experiments induced SCEs. Most inhibitors did not modify the SCE frequencies except for ara C which synergistically increased the frequency in MMC-treated cells. The present study offers further evidence that the lesions responsible for chromosome-type aberrations are those which are repaired quickly, and that they are converted to chromosome-type aberrations when repair by polymerase alpha is inhibited. The effects of ara C on MMC-induced lesions are considered residual effects of ara C treatment in the S or G2 phases rather than repair inhibition in the G1 phase.

Enhancement of cytogenetic damage by inhibitors of poly(ADP-ribose)polymerase in human lymphocytes exposed to antineoplastics in vivo and in vitro

The effect of benzamide (B) and 3-aminobenzamide (3-AB) on sister chromatid exchanges (SCEs) and cell kinetics induced in vitro by melphalan (MELPH) or thiotepa (THIO) was studied in normal human lymphocytes. The combined treatments with either MELPH or THIO plus B or 3-AB showed the potentiating ability on SCE rates and the ability to induce cell division delays of the latter chemicals. In a combined in vivo and in vitro study, lymphocytes taken from six cancer patients who had been given cytoxan by injection 2 hr before and then treated with theophylline (THEOPH) or B or 3-AB in vitro were found to have synergistically increased exchange rates and cell division delays. The frequency of SCEs in the patients own lymphocytes with and without exposure to inhibitor of Poly(ADP-ribose) polymerase (P(ADPR)polymerase) was determined before the cytostatic therapy and was used as a control for later comparison in each individual case. These results further substantiate the use of this approach for detecting the induction of cytogenetic damage concerning controlled mutagen human exposure in combined in vivo and in vitro studies. Chemically induced cytotoxicity manifested as an alteration (division delay) in cell kinetics and as synergistic DNA damage by cytostatics and inhibitors of P(ADPR)polymerase may be of use in the treatment of human cancer.

Induction of sister-chromatid exchanges and cell-cycle delays in human lymphocytes by vitamin A alone or in combination with melphalan and caffeine

In cultured human lymphocytes vitamin A was found to increase SCE rates, to reduce the mitotic index and to have no effect on cell kinetics. Vitamin A induces cytotoxic effects: in combination with melphalan (MELPH), as can be deduced from the resulted synergism on induction of SCEs, the produced cell division delay and the suppressed mitotic index; in combination with caffeine (CAF), producing synergism on induction of SCEs and suppressing the mitotic index; and in combination with MELPH and CAF, producing cell-cycle delays and reducing the mitotic index.

Synergistic induction of sister-chromatid exchanges in lymphocytes from normal subjects and from patients under cytostatic therapy by inhibitors of poly(ADP-ribose)polymerase and antitumour agents

The effects of nicotinamide on SCE rates induced in vitro by chlorambucil (CBC or melphalan (MELPH) or mitomycin C (MMC) was studied. The combined treatments with either CBC or MELPH or MMC and nicotinamide showed the potentiating ability of the latter drug. Theophylline and MELPH were also found to act synergistically on the induction of SCEs. In a combined in vivo and in vitro study, lymphocytes taken from 7 cancer patients who had been given cytoxan by injection 3 h before, were treated with nicotinamide or diphylline (DP) in vitro, and found to have synergistically increased exchange rates. This has implications for interpreting the repair processes involved, for monitoring drug combinations that synergistically damage DNA in vivo and in vitro and for identifying interindividual variation in the response to the treatment.

Practical applications of the SCE studies for guiding and improving chemotherapy

The effect of diphylline (DP) or (1,2-dihydroxy-3-propyl)-theophylline and theobromine (TB) on sister chromatid exchange (SCE) rates induced in vitro by cytosine arabinoside (AraC) was studied in normal human lymphocytes. The combined treatments with AraC plus DP or TB showed the potentiating ability of the latter drugs. In a combined in vivo and in vitro study, lymphocytes taken from 14 patients suffering from various types of cancer who had been given Cytoxan (5 patients) or AraC (9 patients) by injection 3 hr before and then treated with DP or TB in vitro were found to have synergistically increased exchange rates. This has implications for interpreting the repair processes involved and for monitoring drug combinations that synergistically damage DNA in vivo and in vitro.

Selective inhibition of replicative and repair DNA synthesis in mouse colon following administration of 1,2-dimethylhydrazine

Early alterations in normal semiconservative and repair DNA synthesis were determined in gastrointestinal tissues of HalCR mice following administration of the colon carcinogen 1,2-dimethylhydrazine (DMH). Following DMH injections of 60 and 200 mg/kg, normal DNA synthesis was rapidly inhibited in all tissues. The greatest depressions were observed in the descending colon, followed closely by the ascending colon. DNA repair was estimated by measuring unscheduled DNA synthesis. No repair was observable in the descending or ascending colon. The esophagus, forestomach, jejunum, and ileum demonstrated significant amounts of DNA repair, while the duodenum and gastric stomach displayed nominal or insignificant amounts of repair. Repair DNA synthesis was inhibited by simultaneous administration of caffeine and DMH. The degree of inhibition of normal replicative DNA synthesis and the amount of repair DNA synthesis in response to DMH treatment correlate closely with the incidence of DMH-induced tumors. Most tumors occur in the descending colon, followed by the ascending colon, and only a few in the duodenum and gastric stomach area. Neoplasms are rarely found in the remainder of the gastrointestinal system.

Enhancement by methylxanthines of sister-chromatid exchange frequency induced by cytostatics in normal and leukemic human lymphocytes

The effect of theobromine (TB) and diphylline (DP) or (1,2-dihydroxy-3-propyl)theophylline on SCE rates induced in vitro by mitomycin C (MMC), and the effect of caffeine on SCE rates induced in vitro by cytosine arabinoside (Ara-C) was studied. The combined treatments with MMC plus TB or DP showed the potentiating ability of the latter drugs. Caffeine also enhanced SCEs induced by Ara-C in cultured human lymphocytes. Caffeine and adriamycin (ADR) did not act synergistically on induction of SCEs. In a combined study, in vivo and in vitro, lymphocytes taken from 2 leukemic patients who had been given chlorambucil (CBC) or Ara-C by injection 3 h before, and then treated with caffeine in vitro, were found to have synergistically increased exchange frequencies.

SCE evaluations in human lymphocytes after G0 exposure to mitomycin C. Lack of expression of MMC-induced SCEs in cells that have undergone greater than two in vitro divisions

We conducted a series of experiments designed to determine whether DNA damage induced in G0 lymphocytes by mitomycin C (MMC) would be expressed as sister-chromatid exchanges during the second and third post-treatment cell cycles. Lymphocytes from normal donors were exposed to MMC for 2 h prior to culture in the presence of phytohemagglutinin. MMC-treated and control cells were subsequently exposed to bromodeoxyuridine (BrdUrd) for the entire culture period (i.e. 48 h or 72 h) or for the terminal 24 h of 72-h cultures. We observed a 3-4-fold increase in SCEs in MII metaphases from lymphocytes treated with MMC and cultured in the presence of BrdUrd for the entire culture period. In contrast, in replicate cultures of MMC-treated lymphocytes that were exposed to BrdUrd for the terminal 24 h only, the SCE frequency in uniformly harlequinized metaphases was not significantly different from that observed in control cultures. We interpret these data as providing evidence that MMC-induced lesions (or alterations) in the DNA of G0 lymphocytes are probably expressed as SCEs during the first period of mitogen-induced DNA synthesis, and that these lesions do not persist and give rise to SCEs in subsequent cell divisions.

Induction of sister chromatic exchanges and inhibition of cellular proliferation in vitro. I. Caffeine

Cytogenetic assay systems based on the detection of sister chromatid exchanges (SCE) are widely advocated as a sensitive screening method for assessing genotoxic potential. While many agents have been examined for their ability to induce SCE's, complete dose-response information has often been lacking. We have reexamined the ability of one such compound-caffeine-to induce SCEs and also to inhibit cellular proliferation in human peripheral lymphocytes in vitro. An acute exposure to caffeine prior to the DNA synthetic period did not affect either SCE frequency or the rate of cellular proliferation. Chronic exposure to caffeine throughout the culture period lead to both a dose-dependent increase in SCEs (SCEd or doubling dose = 2.4 mM; SCE10 or the dose capable of inducing 10 SCE = 1.4 mM) and a dose-dependent inhibition of cellular proliferation (IC50 or the 50% inhibition concentration = 2.6 mM). The relative proportion of first generation metaphase cels, an assessment of proliferative inhibition, increased linearly with increasing caffeine concentrations. However, SCE frequency increased nonlinearly over the same range of caffeine concentrations. Examination of the ratio of nonsymmetrical to symmetrical SCEs in third generation metaphase cells indicated that caffeine induced SCEs in equal frequency in each of three successive generations. The dependency of SCE induction and cellular proliferative inhibition on caffeine's presence during the DNa synthetic period suggests that caffeine may act as an antimetabolite in normal human cells. The significance of these results in regard to both caffeine's genotoxic potential and to the reliability of the SCE assay system are discussed.

Variations among species and cell types in the effects of caffeine on mutagen-induced cytotoxicity and postreplication repair of DNA

The influence of caffeine on cytotoxicity and postreplication repair of DNA was examined following exposure of several cell types to physical and chemical agents known to damage DNA. The cell types used in this study were normal human fibroblasts (HS-WP), human xeroderma pigmentosum fibroblasts (SGL), Chinese hamster V79 cells, mouse BALB/c-3T3 cells, and secondary Syrian hamster embryo cells. The DNA damaging agents were ultraviolet light (UV), N-2-acetoxy-fluorenylacetamide (AFAA), nitroquinoline-N-oxide (NQO) and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). Induction of cytotoxicity in Chinese hamster V79 cells due to ultraviolet light or AFAA exposure was enhanced by caffeine at a concentration of 1.0 mM in the culture medium, but not at 0.2 or 0.05 mM. Caffeine also inhibited postreplication repair in these cells at the same concentrations. In contrast, postreplication repair was not affected by caffeine at concentrations up to 1.0 mM in normal human fibroblasts (HS-WP), human xeroderma pigmentosum fibroblasts (SGL), secondary Syrian hamster embryo cells, and mouse BALB/c-3T3 cells following treatment with ultraviolet light, AFAA, NQO, or MNNG. Cytotoxicity in BALB/c-3T3 cells following exposure to ultraviolet light or AFAA was enhanced in the presence of caffeine at 1.0 or 0.2 mM, although these concentrations of caffeine had no effect on postreplication repair in these cells. The inhibitory effect of caffeine on postreplication repair was found only in Chinese hamster V79 cells among the five cell types used in this study. Both normal and xeroderma pigmentosum human cells repaired mutagen-induced DNA damage equally well in the absence or presence of caffeine at concentrations of 1.0 mM or less.

Sister chromatid exchange (SCE) and structural chromosome aberration in mutagenicity testing

Data from previous studies published on the induction by mutagens of sister chromatid exchanges (SCEs) and structural chromosome damage were compared qualitatively and quantitatively. Although a good correlation between the incidence of both cytogenetic phenomena has been pointed out in many previous publications, about 30% of the agents for which comparable data were available yielded non-corresponding qualitative results concerning both indicator effects. However, even in groups with good qualitative agreement distinct quantitative differences indicated different molecular mechanisms of the formation of SCEs and breaks. Additional information supporting the importance of these differences for the validity of both indicator systems has been derived from the results obtained using strong clastogens exhibiting a low or no SCE-inducing activity and vice versa, from special observations on chromosomal breakage syndromes, and from studies on the action of known co- and anti-clastogens on SCE-induction by chemical mutagens. As a result, it has been suggested that the SCE-technique should be considered as a valuable additional method for cytogenetic mutagenicity testing, which, however, is not adequate to replace the classical methods of analysis of structural chromosome damage.

Sister-chromatid exchanges: a report of the GENE-TOX program

The effects of a number of chemicals on sister-chromatid exchange (SCE) frequencies in in vivo and in vitro systems are reviewed. Standardized protocols for future SCE testing in important systems, as well as for evaluation of test results, are presented. Data reported thus far suggest that SCE analysis may prove useful, especially at a secondary level, as a test of mutagenic carcinogens. Strengths and limitations of SCE analysis are summarized as a guide for future evaluation and use of this procedure.

Physical, chemical, and biological factors affecting sister-chromatid exchange induction in human lymphocytes exposed to mitomycin C prior to culture

In experiments to assess the effects of several biological, chemical, and physical variables on sister-chromatid exchange (SCE) induction in cultured lymphocytes exposed to mitomycin C (MMC) before PHA stimulation we observed: (1) high SCE frequencies in female cells, and normal SCE frequencies in Y-bearing metaphases in mixed cultures containing equal numbers of MMC-treated female lymphocytes and untreated male lymphocytes; (2) small, but statistically significant, decreases in SCEs with increasing pH after G0 exposure in the pH range 6.6-7.6; (3) pronounced reductions in MMC-induced SCEs in lymphocytes exposed at 4 degrees C vs. 37 degrees C. In other studies, SCE induction was evaluated in cultures exposed during G0 to MMC concentrations ranging from 0.25 to 2.5 microgram/ml for varying time intervals ranging from 5 min to 24 h. For all concentrations tested SCE induction varied as a linear function of G0 exposure time. To compare SCE induction between cultures, we calculated the mean frequencies of SCEs induced per metaphase/unit dose MMC/unit G0 exposure time (SCE/microgram/h). A mean frequency of 20.7 +/- 4.8 SCE/microgram/h was observed for 41 lymphocyte cultures suggesting that a single term adequately describes the rate of SCE induction following G0 exposure to a 10-fold range in concentration of MMC for time intervals of 30 min to 24 h.

Chromosome aberration formation and sister chromatid exchange in relation to DNA repair in human cells

Apparent association between the ability to induce chromosome aberrations and sister chromatid exchanges and mutagenic-carcinogenic potential found in a variety of physical and chemical agents has led us to speculate that these cytogenetic changes might be reflection of DNA damage and repair and might provide induces of mutagenic changes. However, the mechanisms of their formation and their relation to DNA repair as well as the mechanism of their linking to mutation are by no means well understood. Studies in some human genetic mutant cells defective in their ability to repair DNA damage indicate, as a testable proposition, that sister chromatid exchanges and chromosome aberrations are cytological manifestations of replication-mediated dual-step repair pathways that are in operation to tolerate DNA damage when damage-bearing DNA enters and passes through semiconservative replication. The observations are also in line with idea that the majority of sister chromatid exchanges can arise when damage DNA attempts replication possibly by a process relating with the replicative bypass repair mechanisms such as those proposed by Fujiwara and Tatsumi [34] and Higgins et al. [54], while chromosome aberration formation and some fraction of sister chromatid exchanges are related with the post-replication repair processes which attempt to rescue damaged template post-replicationally by de novo synthesis or recombination type repair systems. The former sister chromatid exchange-relating process seems to link mutation to less extent, if any, than the latter process, which is caffeine sensitive and likely to be error-prone.

The effect of caffeine on cytotoxicity, mutagenesis, and sister-chromatid exchanges in Chinese hamster cells treated with dihydrodiol epoxide derivatives of benzo[a]pyrene

The effect of caffeine on Chinese hamster V79 cells after treatment with the highly mutagenic (+/-)-7 beta,8 alpha-dihydroxy-9 alpha, 10 alpha-7,8,9,10-tetrahydrobenzo[a]pyrene, and the weaker mutagen (+/-)-7 beta,8 alpha-dihydroxy-9 beta,10 beta-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene, B[a]P-deiol-epoxide II, was studied at both the biological and molecular levels. Caffeine, at nontoxic dose levels, caused a synergistic reduction in cell survival induced by both isomers and also inhibited DNA elongation as measured by alkaline sucrose-gradient analysis of nascent DNA. However, caffeine did not affect the induction of either ouabain-resistant mutants or sister-chromatid exchanges by either isomer. These results suggest that enhanced cell killing by caffeine in benzo[a]pyrene-diol-epoxide treated V79 cells may be related to caffeine's inhibitory effect on DNA elongation. However, inhibition of DNA elongation by caffeine did not influence the resulting induced levels of mutagenesis or sister-chromatid exchanges.

Effects of caffeine on chromosome aberrations and sister-chromatid exchanges induced by mitomycin C in BrdU-labeled human chromosomes

The BrdU-Hoechst staining technique has been used in analyzing the effect of caffeine (CAF) on chromosome aberrations and sister-chromatid exchanges (SCEs) induced by mitomycin C (MC). CAF increased the frequency of SCE in MC-treated chromosomes in all specimens. The combination of MC and CAF caused a remarkable increase in all types of chromosome aberrations, but the most startling effect was the appearance of many cells with multiple aberrations (shattered chromosomes). The BrdU-Hoechst technique showed that the shattered chromosomes did not appear in cells that had replicated only once, but did occur in cells which replicated twice in the presence of MC and CAF. The large majority of chromatid breaks observed did not involve areas common to SCE; and the SCE frequency significantly increased in spite of the existence of multiple breaks. This indicates that very few of the breaks are incomplete exchanges and that the mechanism for formation of SCE might be different from that of chromosome breaks. In another experiment, monofunctional-MC (M-MC) had a small effect on SCE rates, though it induced shattered chromosomes with CAF post-treatment. Possible differences in the mechanisms leading to SCE and chromosome breaks are discussed.

Sister-chromatid exchanges in human lymphocytes exposed during Go to four classes of DNA-damaging chemicals

Human lymphocytes were treated prior to mitogenic stimulation with varying concentrations of 6 cytostatic drugs representing 4 classes of DNA-damaging chemicals. Afterwards the cells were washed to remove residual chemical and cultured in the presence of bromodeoxyuridine for analysis of sister-chromatid exchanges (SCEs). A dose-related increase in SCEs was observed in cells exposed during Go to the alkylating chemicals mitomycin C, chlorambucil, and thiotepa, while significant increases in SCEs were not noted in cultures exposed to methotrexate, cytarabine, or bleomycin. These findings suggest that not all classes of clatogenic chemicals which induce SCEs in proliferative cells substituted with BUdR are capable of inducing long-lived lesions in the DNA of Go lymphocytes that can lead to SCE formation.